JP2023543923A - floor plan visualization system - Google Patents

Abstract

In one embodiment, a floor plan visualization system is provided. The system includes a visualization studio, a matrix of floor-mounted visual display units forming a floor surface of the visualization studio, a controller computer with a user interface, and a controller computer operatively connected to the matrix of visual display units. and a video output for controlling the video displayed from the visual display unit. In use, the controller computer is configured to receive floor plan representation data, segment the floor plan representation data into a plurality of display segments, and output the plurality of display segments to respective visual display units.

Description

The present technology relates to a floor plan visualization system. In some embodiments, the floor plan visualization system is a mobile floor plan visualization system that can be deployed in any suitable space.

BACKGROUND OF THE INVENTION Residential and/or commercial buildings are constructed from floor plans that are drafted, inspected, and, if necessary, adjusted prior to construction. Floor plans are typically created at a scale that allows representation on, for example, an A3 page format.

Prior to construction, the floor plan will be inspected and adjustments made accordingly. For example, the floor plan may be adjusted according to the "feel" of the interior with reference to proposed furniture, appliances, and/or other amenities.

However, it is difficult to make such adjustments on paper format, and advanced architecture 3D rendering software is used not only to locate the proposed equipment, but also to provide interior virtualization. can be done.

However, the use of virtualization software is not always appropriate to determine the suitability of the layout or to make adjustments accordingly.
At least some of these issues have been kept in mind in developing the present invention.

In the context of this specification, the term "floor plan" may provide information to a user regarding the size, shape, features, and other attributes of a structure (such as a house, apartment complex, or any type of building). Contains any possible set of images.

Generally, one or more aspects of the invention provide a floor plan visualization system. The floor plan visualization system includes a matrix of visual display panels arranged within a visualization studio to substantially cover a floor surface of the visualization studio. A controller computer is used to provide floor plan data to each visual display panel of the matrix of visual display panels. The controller computer includes a user interface and a display image output. A display image output is operably coupled to each of the visual display panels to control the image displayed on each of the visual display panels.

As such, the controller computer is configured to segment the floor plan into a plurality of segments for display by each of the visual display units located on the floor surface of the visualization studio.

The controller computer is configured to adjust the scale so that the displayed floor plan is at real world (1:1) scale. In that way, a user, such as a prospective purchaser, can walk over the matrix of visual display panels (i.e., over the displayed floor plan in operation), thereby allowing the This allows the user to more accurately gauge the feel of a proposed layout within the visualization studio, and thus its suitability.

In addition, real-size physical objects (such as chairs, tables, and other furniture, and appliances) can be placed on the floor surface for visual inspection thereof. In one embodiment, the physical object is placed on a wheel, roller, or equivalent device arranged to allow easy movement of the object from one part of the visualization studio to another. Ru.

The controller computer can scale the floor plan representative data accordingly for accuracy. For example, a user can adjust the scale using a user interface, and in embodiments, the controller computer can display a scale overlay that can be referenced when making such adjustments. In further embodiments, the controller may interpret scale markings on the representation data or interpret scale metadata for appropriate initial adjustment of the scale. In yet a further embodiment, the size of each of the visual display units may be input to the controller computer to enable the controller computer to adjust the scale of the image displayed on each of the visual display units. In this way, different visual display units of different sizes can be used in the matrix.

In a further embodiment, the controller computer is configured for on-floor user interaction.
For example, in one embodiment, the controller computer is configured to ascertain the location of the user on the floor surface, such as by using image analysis. The controller computer may ascertain the user's location, for example, by communicating with a mobile computing device held by or carried by the user. Alternatively, the controller computer may use a camera and image recognition software to identify the user's location within the visualization studio. In a third embodiment, the matrix of visual display units includes a pressure sensitive surface, and feedback received by the controller computer from the pressure sensitive surface may determine the location and movement of the user.

In that way, and in particular for floor plans that do not fit within the available surface area within the visualization studio, the controller computer can modify the floor plan representation displayed on the matrix of visual display units according to the user's position. , pan, change, or perform other operations.

Additionally, the floorplan representative data may be enriched with user interaction data in relevant interaction areas of the floorplan representation. For example, the user interaction area may be configured such that when the user's location is determined to coincide with the user interaction stairwell area, the controller computer replaces the floor plan representation with the floor plan from the floor above or below accordingly. A stairwell can be expressed. In that way, users can virtually walk between floors.

The controller computer may also be configured for other aspects, such as virtual furniture, appliances, etc. In addition to this, the controller computer generates a visual image that acts as an overlay, allowing for substitutions such as the color of the carpet within specific areas of the floor plan, such as the living area, kitchen area, or other areas. Allows for replacement.

In a first aspect, a floor plan visualization system is provided. The system includes a visualization studio, a matrix of generally flat visual display units mounted to substantially cover the floor of the visualization studio and capable of displaying images, and a controller computer. and the controller computer includes a user interface and a video output, the video output being operably coupled to the matrix of visual display units for controlling images displayed from the video output. , in use, the controller computer is configured to receive floor plan representation data, segment the floor plan representation data into a plurality of display segments, and segment the plurality of display segments into respective visual display units. outputting, and the controller computer is configured to receive scale adjustment commands via a scale adjustment control of the user interface and to display a floor plan representation on the floor surface. and adjusting the scale of the segment of the computer to a real-world scale.

The floor plan visualization system may further include a user position monitoring subsystem for detecting a user's position on the floor surface. The user location subsystem may be provided by interaction with a device held by the user, and may be provided by the use of sensors, such as pressure sensors, cameras, or any other suitable sensing technology.

The controller may be configured to change the floor plan representation according to the location of the user. Modifications may include panning and/or changing the representation of the floor plan in part or in whole.

The controller computer may be further configured to receive floor plan interaction data representing one or more user interaction areas and associated interaction actions on the floor plan representation, the location of the user and the one When a match with the above user interaction area is detected, the related interaction action may be executed.

The associated interaction action may include replacing the floorplan representation with another floorplan representation.
The matrix of user interfaces and/or display panels may incorporate a touch-sensitive user interface configured to receive on-screen user gestures. The controller may be configured to display corresponding markings at respective locations on the floor plan representation.

The matrix of user interfaces and/or display panels may be a touch-sensitive user interface configured to receive on-screen cut and drag user gestures, and the controller is configured to receive on-screen cut and drag user gestures. The subregion of the floor plan representation may be manipulated according to the method.

The controller computer may be configured to enhance the floorplan representation with one or more of textures and color overlays.
The controller computer may include a database regarding a plurality of overlays, and in use, the controller computer receives a selection of one of the plurality of overlays via the user interface and selects the selected overlay. may be configured to extend one region of the floorplan representation using the floor plan representation.

Floor plan representative data may include area representative metadata, and the controller computer may be configured to overlay the overlay onto the area represented by the area representative metadata.

The controller computer may be configured to determine the area representative metadata using image analysis of the floor plan representative data.
The controller computer may include a database of a plurality of object representations, and in use, the controller computer receives object selections via the user interface and makes representations of the object selections using the user interface. and overlaying the floor plan representation at locations specified by the floor plan representation.

In a second aspect, a floor plan visualization system is provided. The system includes a visualization studio including one or more walls and is mounted to substantially cover at least a portion of the one or more walls of the visualization studio and is capable of displaying an image. , a matrix of substantially planar visual display units, and a controller computer, the controller computer having a user interface and a video output, the video output for controlling images displayed from the video output. is operably coupled to the matrix of visual display units, and in use, the controller computer receives wall plan representation data and segments the wall plan representation data into a plurality of display segments. and outputting the plurality of display segments to respective visual display units, the controller computer receiving scale adjustment commands via a scale adjustment control of the user interface. and adjusting the scale of the segment for displaying the floor plan representation on the wall to a real-world scale.

Other aspects of the invention are also disclosed.
Further features of the invention are described more fully in the following description of some non-limiting embodiments thereof. Such descriptions are included for the purpose of illustrating the invention only and are not to be understood as limitations on the broad summary, disclosure, or description of the invention set forth above. In the following description, reference is made to the accompanying drawings.

FIG. 1 depicts a floor plan visualization system according to one embodiment of the invention. FIG. 2 illustrates an example illustrator floor plan visualization studio, according to an embodiment of the present disclosure.

In the detailed description of FIGS. 1-2 below, like numbers refer to like features and/or integers throughout FIGS. 1 and 2.
In the embodiments described herein, a floor plan visualization system 1 is provided. The system 1 is configured to allow visualization of a floor plan, which in one preferred embodiment is scaled to real-world dimensions. System 1 has applications for enabling pre-construction inspection of proposed floor plans, thereby preventing or reducing the likelihood that post-construction modifications will be required.

Referring now to FIG. 1, a functional and logical schematic diagram of a system 1 for visualization of scaled floor plans is shown. System 1 includes a computer controller 19 . As described in more detail below, the computer controller 19 receives the floor plan data and displays the floor plan data using one or more visual display panels (such as an electronic paper panel), as described herein. (see, e.g., https://en.wikipedia.org/wiki/Electronic_paper), however, a light emitting diode panel, a liquid crystal display panel, or any It is understood that any suitable "flat screen" display panel may be used, including other suitable technologies.

This embodiment uses an electronic paper display panel because it requires little power consumption and the image is "held" for a period of time even when no power is applied to the panel.

Specifically, referring now to FIG. 2, an example floor plan visualization studio 21 is shown. As can be seen, the studio 21 includes a plurality of visual display panels 23 disposed on a floor surface 25, the floor surface 25 having a pressure sensitive layer ( (not shown). In some embodiments, the panel is covered with a see-through protective layer such as a Perspex layer or other transparent plastic, glass (or similar surface) to prevent scratches and protect the user and/or panel. Additional protection against compressive forces exerted by overlying furniture can be provided. As will be appreciated, the user 28 stands on or adjacent to the surface 25 so that the displayed floor plan 26 can be visualized for pre-construction inspection.

Referring again to FIG. 1, it will be appreciated that the controller 19 comprises a processor 11 for processing digital data. In operative communication with processor 11 via data bus 37 is memory/storage device 9 .

Memory device 9 is configured to store digital data including computer program code for execution by processor 11 . In particular, memory device 9 may include multiple computer modules 8 configured to implement the various functions described herein. Furthermore, memory device 9 may include a database/data store 10 for storing various data, including those described herein.

In embodiments, memory device 9 may take the form (or combinations thereof) of volatile RAM or non-volatile ROM memory storage, and hard drive storage (including physical and solid state hard drive storage).

Controller 19 further includes a data interface 7 . Data interface 7 is configured to receive data from various peripheral components, including those described herein. In some embodiments, data interface 7 may be displayed on a mobile computing device such as a smartphone or tablet computing device carried by the user.

In one embodiment, data interface 7 comprises a USB host controller, but is not necessarily so limited. As shown in Figure 1, the data interface 7 is configured to read data from a computer readable medium 2, such as a USB drive.

In this regard, with reference to embodiments described herein, data interface 7 is configured to receive floor plan data 3 from computer-readable medium 2 for the purpose of visualizing the floor plan in accordance with the techniques described herein. It's okay to be.

Thus, in use, the user 28 provides the floorplan data 3 to a USB memory stick device or the like connectable to a plug of the computer controller 19 for display purposes. However, the floorplan data 3 may also be provided in other ways.

Data interface 7 may additionally be configured to interact with user interface 34 . For example, in embodiments, user interface 34 may include a display device 35, such as a touch screen LCD display device 35. In this regard, display device 35 may display a graphical user interface 36 that may be used by user 28 to interact with computer controller 19 in the manner described herein.

Furthermore, the computer controller 19 includes a video interface 12 for outputting video data to one or more visual display units 23 located within the floor of the studio 21. In one preferred embodiment described herein, the system 1 comprises a matrix 22 of visual display units 23 configured for segmented display of floor plan data. As such, the viewer interface 12 may be a multi-output video interface 12 having a respective output for each of the visual display units 23. In an alternative embodiment, the visual display units 23 may be configured to form a "chain" together (i.e., directly connected to each other), with a subset of the visual display units designated as a "master" display unit (i.e. , connected to the controller 19 and receiving video data from the controller 19) and configured to relay the video data to a “slave” visual display unit 23. Such variations are within the purview of those skilled in the art.

In embodiments, system 1 may be configured for user position determination for user interaction. In this regard, in one embodiment, the system 1 may include an image capture device 24 for capturing image data for image processing to identify the position of the user 28 on the floor surface. Alternatively, the user's location may be determined by using the location of a portable device held by the user, such as a smartphone or tablet computing device. In a third embodiment, a pressure sensor overlaying the visual display unit 23 may provide feedback data to the controller 19 to determine the user's location.

System 1 will now be described, primarily for purposes of illustration, with reference to one or more exemplary embodiments. Note that the embodiments shown below are merely examples, and no technical limitations are attached to all of these embodiments.

Referring to FIG. 2, as mentioned above, studio 21 may be provided for floor plan visualization purposes. In this regard, one or more visual display units 23 are mounted on the floor for display on a surface 25 within the studio 21. Surface 25 is a floor in the described embodiment. However, it is understood that the visual display unit may be attached to at least a portion of one or more walls of the visualization studio.

In various embodiments, the surface 25 may have dimensions of approximately 40 x 17 m2, but the implementations described herein with respect to allowing the user 28 to visualize the displayed floor plan. Other dimensions may be suitable within the scope of the configuration objectives.

In a preferred embodiment shown in FIG. 2, the visual display units 23 are arranged in a matrix 22. In this regard, each visual display unit 22 may be configured to display a respective segment of the displayed floor plan 26.

Furthermore, as mentioned above, in embodiments, the system 1 includes one or more image data of the user 28 from the surface 25 for purposes of user interaction, as described in more detail below. An image capture device 24 may be included.

As can be seen from FIG. 2, the floor plan 26 displayed on the surface 25 may display various elements of the floor plan 26, such as a bathroom 30, a kitchen 29, a bedroom 21, a storage room 32, etc. Furthermore, in the embodiment shown, a stairwell 33 is provided. In this regard, in embodiments as described above, system 1 may be configured for user floorplanning interaction during use. In those embodiments, the system 1 can determine when the user walks through the stairwell 33 so that the floor plan can transition to the next upper or lower floor.

Furthermore, as can also be seen from FIG. 2, the floorplan 26 may include a scale overlay 27 that may be referenced to adjust the scale of the floorplan 26.
Now, having configured the studio 21 in the manner described above, the user 28 may wish to visualize the floor plan 26 of the proposed building. In embodiments described herein, floor plan 26 includes multiple floors for a multi-story building.

As such, the user 28 loads the floor plan data 3 onto the computer readable medium 2, such as a USB memory stick. As understood from FIG. 1, the floor plan data 3 can include multiple floors 4 representing multiple floors. The floor 4 may be of different types. In one embodiment, floor 4 is provided in PDF format. However, in other embodiments, the floor 4 may be provided in a proprietary architectural software format for interpretation by the computer controller 19.

In embodiments, additional data may be loaded onto the computer-readable medium 2 for the purpose of enhancing the user experience in visualizing the floor plan 26. In particular, as will be understood, the floor plan data 3 may further include interaction data 5. Such interaction data 5 may be used for user interaction purposes in several embodiments, as explained in more detail below.

Furthermore, various configuration data 6 may also be provided in connection with the floor data 4. Such configuration data 6 may configure various aspects including the manner in which the floor 4 is displayed, such as coloring and scale. Furthermore, the configuration data 6 may configure the order of the floors 4 in descending order of height. Upon arrival at the studio 21, the computer readable medium 2 is inserted into the data interface 7 for reading.

Controller 19 may read floor plan data 3 from computer readable medium 2 , and floor plan data 3 may then be stored in database 10 . As will be appreciated, database 10 may replicate various data, including storing floors 4, interaction data 5, and configuration data 6.

It should be noted that in embodiments such data does not necessarily need to be stored within database 10 instead of controller 19 using data on computer readable medium 2 directly.

It will be understood here that the computer module 8 may be equipped with a display module 13 for the purpose of displaying the floor plan 26. In particular, display module 13 converts floor plan data 3 into a format suitable for output via video interface 12 for display by visual display matrix 22 . As mentioned above, display module 13 may operate according to configuration data 6 that specifies aspects of how floorplan 26 is displayed, scaling of the floorplan, etc.

As will be appreciated, the computer module 8 may further include a segmentation module 14 for segmenting the floor plan 26 through various visual displays 23. In particular, in the embodiment shown in FIG. 2, a matrix 22 of six visual displays 23 may be provided. In this regard, segmentation module 14 may segment floor plan 26 into six corresponding segments for each display by six visual displays 23.

In embodiments, the visual display 23 may have a "border" or "rim" around which images cannot be displayed. In this embodiment, the controller 19 adjusts the location of the various segments such that the entire displayed image remains scaled even though a small portion of the image at the edge of each visual display unit is not displayed. may be configured to do so.

Computer module 8 may further include a scaling module 15 configured to scale floor plan 26 appropriately. In embodiments, as described above, scaling module 15 may be configured to interpret scaling data within configuration data 6.

For example, the scale may be specified by the floor plan data 3, which may be configured according to the dimensions of the entire surface 25, and the scaling module 15 may cause the floor plan 26 to scale to real-world dimensions. , configured to scale the floorplan appropriately.

As such, the floor plan item appears to the user 20 standing on the entire surface 25 as being of real world size. In that way, the user can visually check the size of the floor plan so that he can take corrective action if necessary in the building forecast.

In embodiments, scaling module 15 may interpret scale data of the floor plan representation, such as by performing optical character recognition (OCR) and width measurements of scales displayed thereon. Alternatively, scaling module 15 may interpret scaling metadata that accompanies the representation data.

In embodiments, computer module 8 may include a configuration module 16 to enable configuration of displayed floor plan 26. In one embodiment, configuration module 16 is configured to allow user adjustment of the scaling of displayed floor plan 26.

For example, in the embodiments described above, display module 13 may be configured to overlay scale overlay 27 on floor plan 26 . Such a scale overlay 27 may have a set length, such as a length of 1 m. As such, the user may place a physical object of the same size, such as a metric scale, adjacent to the scale overlay 27 so that the scaling of the floor plan 26 can be adjusted accordingly. In particular, if the metric length and scale overlay 27 do not match, the user may increase or decrease the scale of the displayed floor plan 26 using the user interface 34.

For example, user interface 34 may display scale adjustment controls, such as slider controls, that the user can use to cause scaling module 15 to issue scale up and scale down adjustments to make the necessary adjustments. can. In that way, the user adjusts the scale adjustment controller until the virtual scale overlay 27 matches the reference object in length.

In further embodiments, system 1 may analyze image data captured by image capture device 24 to make image adjustments. For example, for a floor plan scale legend, the controller 19 uses the image data captured by the image capture device 24 to calculate the actual length shown on the studio floor surface in order to make the necessary adjustments. can be determined. To be able to ascertain the proper scale of the floorplan scale legend, the controller may further implement OCR of the floorplan representation to read and interpret the proper scale.

In other embodiments, the configuration module 16 may allow the user to configure other aspects of the displayed floor plan 26, such as coloring. For example, floor plan 26 may be displayed with a white or black background. Such configuration may similarly be implemented by user 28 using user interface 34.

In embodiments, computer controller 19 may be configured for user floorplanning interaction during use. In this regard, controller 19 may include an interaction module 17 configured to implement the various user interactions described herein.

In one embodiment, the controller 19 may allow the user to switch between different floors 4 of the floor plan data 3. For example, using the user interface at 34, user 28 may switch between multiple candidate floorplans 26. In an alternative embodiment, user 28 may use user interface 34 to switch between the upper and lower floors. For example, a user may first view the ground floor and then view the first floor of the building plan.

In embodiments, controller 19 may be configured to determine the location of user 28 for purposes of user interaction. In this regard, as mentioned above, the studio 21 includes one or more cameras 24 configured to capture images of the user 28 to enable the controller 19 to determine the relative position of the user 28. It's okay. In this regard, computer module 8 may include an image processing module 18 for interpreting image data received by image capture interface 20 to determine the location of the user. In other embodiments, other sensor types may be used to determine the user's location.

Once the relative position of the user is determined, in embodiments, the display module 13 may be configured to pan the floor plan 26 according to the location of the user 28. For example, if the real-world scale of floor plan 26 exceeds the available surface area of surface 25, display module 30 may be configured to pan floor plan 26 as the user moves around surface 25. For example, as the user 28 approaches an edge of the surface 25, the display module 13 displays the floor plan in the opposite direction away from the approached edge, allowing the user to see 28 the previously clipped edges of the floor plan. You may pan 26.

In alternative embodiments, the detected location of user 28 may be used for user interaction purposes. For example, in embodiments, controller 19 may be configured to determine a match between a user location and an interaction area.

In detail, as described above, the displayed stairwell 33 may be designated as an interaction area by the interaction data 5 of the floor plan data 3.
As such, if the controller 19 determines that the location of the user 28 coincides with the stairwell interaction area 33, the controller 19 may take appropriate action, such as transitioning to the next floor. In that way, the user can approach the stairwell as if visually climbing up and down the flights of stairs.

In embodiments, configuration data 6 may include surface rendering data that controls how floor plan 26 is displayed. In particular, configuration data 6 may include various surface rendering exemplars, such as displayed floor plans 26, that are toggled or selected using computer controller 19 and updated accordingly. In particular, in this embodiment, different floor types, carpet types, colors, etc. may be displayed substantially dynamically on the floor plan 26. Database 10 may contain such rendering data that may be applicable to all floor plans provided.

The floorplan representation data 4 may include boundary determination metadata that determines the boundaries of various types of regions and thus floor settings of the floorplan representation. For example, boundary metadata allows users to quickly switch between different floor types (e.g., different types of carpet types for hallway areas and different types of non-carpet types for kitchen areas). As such, the hallway area may be selected instead of the kitchen area. In embodiments, controller 19 may implement floorplan continuity analysis so that connected areas of the floorplan can be intelligently "filled" with selected floorplan types.

If at least a portion of the wall includes a visual display unit, the user 28 can view the house elevation 34 relative to the studio wall 21. In this way, the user can make changes to the house, such as by changing the location of exterior doors, windows, siding, facades, etc., if necessary.

In this embodiment, the rendering of the house elevation 34 may be further configured according to the configuration data 6 to allow the user to switch between different exterior primers, paint finishes, etc.

In embodiments, elevation 34 may represent an interior view of a proposed building, and in embodiments, elevation 39 may represent a representation of the elevation 34 that corresponds to It has a corresponding working relationship with the displayed floor plan 26 at its base. Thus, for example, for a kitchen 29 displayed in floor plan 26, the user can additionally see an internal elevation of kitchen 29 as displayed by elevation 34. It is.

In embodiments, elevation 34 may be dynamically generated by computer controller 19 according to floor plan data 4 and configuration data 6. For example, computer controller 19 may generate elevations according to configuration data 6, such as by dynamically generating interior paint colors and dynamically assigning other interior home features such as doors, windows, and kitchen fixtures. 34 can be rendered dynamically. In embodiments, the dynamic generation of interior elevations 34 may be generated according to parameters provided by the user (e.g., if the user specifies kitchen component types), and the computer controller 19 may It may also be a pseudo-randomly generated feature, such as when furniture, potted plants, paintings, etc. are randomly arranged.

In embodiments, partitions, barriers, and false walls may be used to help a user visualize the depth of an enclosed space. Such partitions may be aligned with the boundaries of the displayed floor plan 26 and may include visual representations 23. The use of multiple visual displays 23 may assist in displaying floor plan visual displays 26 on vertical partitions.

In addition to this, a physical movable furniture bed, to further aid the user visualization process so that it is possible to make informed decisions regarding layout, lost space for furniture, etc. Cupboards, tables, chairs, lounges, TV units, etc. may be placed at appropriate locations within the displayed boundaries of the displayed floor plan 26. In an alternative embodiment, the virtual furniture object may be "physically" grasped by the user for repositioning by using gestures detected by camera 24 or controlled using touch-sensitive display 24. The information may be displayed by the controller 19 that may be displayed.

Furthermore, in embodiments, computer controller 19 may be configured to add or remove displayed lines from displayed floor plan 26 in near real time during the visualization process.

Furthermore, the computer controller 19 may be configured to enable the acquisition of measurements. In one embodiment, display 35 may be used to place pointers, rulers, etc. for the purpose of taking measurements. In an alternative embodiment, a visible ruler, tape measure, etc. may be placed through the display surface 26 to be detected by the camera 24 so that measurements can be taken. For example, in one embodiment, a user may extend a pink tape measure through display surface 26 that is detected by camera 24. The controller 19 then takes measurement readings according to the detected length of the tape measure and then protects the measurement readings adjacent to the tape measure. In embodiments, area can be correlated in a similar manner.

In a further embodiment, the system 1 receives the writing gesture by the user interface 34 so that it can display the corresponding writing on the floor surface. For example, user interface 34 may take the form of a mobile computing device held by a user while walking on a floor surface. As such, at the appropriate location, the user virtually writes and marks on the floor surface to create the appropriate marks on the user interface 34. For example, the user can make markings where the wall should be moved.

In further embodiments, using similar gestures, the user modifies the displayed floor plan representation data to use cut, move, and place gestures. For example, a user can draw a bounding rectangle around a wall to be moved and then use a drag gesture to drag the selected area to the next new area to be placed. As a result of such editing process, controller 19 may output modified floorplan representation data that may be used as a basis for modification. Furthermore, in embodiments, controller 19 may be configured to automatically generate design changes determined during the visualization process, which design changes may then be used by architects, engineers, etc. for implementation. The information may also be provided to the person responsible for the authentication, the certifier, etc.

Advantages One of the advantages of the embodiments described herein and the broader invention is that the device provides a cost-effective, reliable, and mobile device for visualizing floor plans on a "life-size" scale. The goal is to provide a device that is possible.

Definitions and Clarifications of Terms Throughout this specification, unless the context requires otherwise, the terms "comprise" or variations such as "comprises" or "comprising" are used throughout this specification. is understood to implicitly indicate the inclusion of the recited integer or group of integers, but not to explicitly exclude any other integer or group of integers.

Those skilled in the art will appreciate that the embodiments described herein are susceptible to obvious variations and modifications other than those specifically described, and that the broadest claims encompass all such variations and modifications. It is understood that this is intended. It will also be understood by those skilled in the art that the inventive concept supporting the broadest claim includes any number of steps, features, and concepts referred to or indicated herein, individually or collectively. It is also understood that any combination of any two or more of these steps or features may constitute an invention.

Where definitions for selected terms used herein are found within the detailed description of the invention, it is intended that such definitions apply to the claimed invention. However, unless explicitly defined otherwise, all scientific and technical terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Claims (13)

A floor plan visualization system comprising: a visualization studio;
a matrix of visual display units consisting of floor-mounted visual display units, forming a floor surface of said visualization studio;
a controller computer, the controller computer comprising:
a user interface;
a video output, the video output being operably coupled to the matrix of visual display units for controlling images displayed from the video output;
In use, the controller computer:
receiving floor plan representative data;
Segmenting the floor plan representation data into a plurality of display segments;
outputting the plurality of display segments to respective visual display units;
the controller computer receives a scale adjustment command via a scale adjustment control of the user interface;
a floor plan visualization system configured to: adjust the scale of the segment for displaying a floor plan representation on the floor surface to a real-world scale; The floor plan visualization system of claim 1, further comprising a user position monitoring subsystem for detecting a user's position on the floor surface. 3. The floor plan visualization system of claim 2, further comprising an image capture device, and wherein the location of the user is determined using image processing of image data captured by the image capture device. 3. The floorplan visualization system of claim 2, wherein the controller is configured to change the floorplan representation according to the location of the user. The controller computer is further configured to receive floor plan interaction data representing one or more user interaction areas on the floor plan representation and associated interaction actions, and the controller computer is further configured to receive floor plan interaction data representing one or more user interaction areas on the floor plan representation and associated interaction actions; 3. The floor plan visualization system of claim 2, wherein upon detecting a match with any of the above user interaction areas, the controller computer is configured to perform the associated interaction action. 6. The floorplan visualization system of claim 5, wherein the associated interaction action includes replacing the floorplan representation with another floorplan representation. The user interface is a touch sensitive user interface configured to receive on-screen user gestures, and the controller is configured to display corresponding markings at respective locations on the floor plan representation. 2. The floor plan visualization system of claim 1. The user interface is a touch-sensitive user interface configured to receive on-screen cut and drag user gestures, and the controller controls a subregion of the floorplan representation according to the cut and drag user gestures. The floor plan visualization system of claim 1, wherein the floor plan visualization system is configured to operate. The floor plan visualization system of claim 1, wherein the controller computer is configured to augment the floor plan representation with one or more of textures and color overlays. The controller computer includes a database regarding a plurality of overlays, and in use, the controller computer receives a selection of one of the plurality of overlays via the user interface and uses the selected overlay. 10. The floorplan visualization system of claim 9, wherein the floorplan visualization system is configured to expand one region of the floorplan representation using the floorplan representation. The floor plan representative data includes area representative metadata,
10. The floor plan visualization system of claim 9, wherein the controller computer is configured to overlay the overlay on a region represented by the region representative metadata. 12. The floor plan visualization system of claim 11, wherein the controller computer is configured to determine the area representative metadata using image analysis of the floor plan representative data. The controller computer includes a database of a plurality of object representations, and in use, the controller computer receives object selections via the user interface and specifies representations of the object selections using the user interface. 2. The floor plan visualization system of claim 1, wherein the floor plan visualization system is configured to overlay the floor plan representation at a location where the floor plan visualization is performed.

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